Sense amplifier common mode dip filter circuit to avoid false misses

ABSTRACT

A high speed compare circuit includes a plurality of bit compare block circuits (0 through N) which are coupled in a wired OR configuration to a match line. Each bit compare block (0 through N) includes a compare circuit for receiving a bit and its complement from word A and a corresponding bit and its complement from word B. The compare circuit includes an output line which is normally maintained high to indicate that a match exists. The output line is coupled to a common mode dip filter which is comprised of N and P channel transistors. The output line of the compare circuit is coupled to the gates of a first and a second P channel transistor. The first P channel transistor is coupled to V cc , and the second P channel transistor is coupled in series to the first P channel transistor. The output line from the compare circuit is also coupled to the gate of an N channel transistor coupled in series with the first and second P channel transistors. The N channel transistor is also coupled to ground. A third P channel transistor is electrically coupled between the first and the second P channel transistors and to ground. A dip filter output line (referred to herein as &#34;compare out&#34;) is coupled between the second P channel transistor and the N channel transistor, as well as to the gate of the third P channel transistor. In operation, the common mode dip filter of the present invention filters relatively short duration voltage dips from the output of the compare circuit. These transient voltage dips may be generated through the use of, for example, sense amplifiers to sense memory locations to retrieve words to be compared by the present invention.

BACKGROUND OF THE INVENTION

The present invention is related to U.S. patent application Ser. No. 08/336,543, filed Nov. 9, 1994, entitled "High Performance Dynamic Compare Circuit", and Ser. No. 08/336,524, filed Nov. 9, 1994, entitled "A Charge Shared Precharge Scheme to Reduce Compare Output Delay," and hereby refers to, and incorporates by reference the content of the above referenced applications herein.

1. Field of the Invention

The present invention is related to the field of data processing systems, and more particularly, the present invention relates to filter circuits for use with digital memories and other devices which require the use of sense amplifiers.

2. Art Background

There are many instances in modem data processing systems wherein a central processing unit (CPU) or other device must determine whether or not two data words are identically equal. For example, a comparison operation between a first and a second data word may be required in the case of a cache memory system in which data words and/or memory tags must be compared, as well as in other digital systems such as encryption devices wherein passwords and the like must be compared for an identical match.

In many instances, at least one of the digital words to be compared may be read by the CPU from memory. As is known, digital memory devices are comprised of electronic memory cells which store either a logical zero or a logical one. To read a cell, the voltage level of the cell must be sensed to determine its logical state. The sensing of the cell is accomplished through the use of sense amplifiers. A natural characteristic of electronic sense amplifiers is that their output voltage may dip prior to providing a final "solid" voltage output level. As will be described, this natural voltage dip may result in spurious signals including false hit or miss conditions during a compare operation.

The present invention provides an improved common mode dip filter circuit, which has particular application for use in electrical circuits wherein sense amplifier voltage dips must be filtered to avoid false hits or misses. Although the present invention will be described with reference to its current implementation in a high performance dynamic compare circuit, it will be appreciated that the present invention may be utilized in a variety of other circuit applications.

SUMMARY OF THE INVENTION

The present invention discloses apparatus and methods for filtering the output of a circuit used to compare the contents of two digital words and determine whether or not they identically match. The high speed compare circuit includes a plurality of bit compare block circuits (0 through N) which are coupled in a wired OR configuration to a match line. Each of the bit compare blocks receives a single bit from a first word A to be compared to a corresponding bit in a second word B. A charge share precharge circuit is coupled to the match line for precharging the match line to a voltage level of V_(cc) /2. A latch is coupled to the match line to electrically latch the state of the match line subsequent to the comparison operation. Each bit compare block (0 through N) includes a compare circuit for receiving a bit and its complement from word A and a corresponding bit and its complement from word B. The compare circuit includes electrically coupled CMOS pass gates to accomplish an exclusive NOR operation between the corresponding bits. The compare circuit includes an output line which is normally maintained high to indicate that a match exists. The output line is coupled to a common mode dip filter which is comprised of N and P channel transistors. The output line of the compare circuit is coupled to the gates of first and a second P channel transistors. The first P channel transistor is coupled to V_(cc), and the second P channel transistor is coupled in series to the first P channel transistor. The output line from the compare circuit is also coupled to the gate of an N channel transistor coupled in series with the first and second P channel transistors. The N channel transistor is also coupled to ground. A third P channel transistor is electrically coupled between the first and the second P channel transistors and to ground. A dip filter output line (referred to herein as "compare out") is coupled between the second P channel transistor and the N channel transistor, as well as to the gate of the third P channel transistor.

In operation, the common mode dip filter of the present invention filters relatively short duration voltage dips from the output of the compare circuit. These transient voltage dips may be generated through the use of, for example, sense amplifiers to sense memory locations to retrieve words to be compared by the present invention. The normally high output line from the compare circuit may dip low as a result of transient voltage swings generated from electrical characteristics of sense amplifiers. The common mode dip filter of the present invention requires that the output line of the compare circuit be driven low in more than a transient manner in order to drive the normally low compare out line of the common mode dip filter to a high state.

The compare out line of the common mode dip filter is coupled to the gate of an N channel transistor in a wired OR circuit. The N channel transistor of the wired OR circuit is coupled between the match line and ground. Since the normal state of the compare out line is low, thereby indicating that match exists, the N channel transistor in the wired OR circuit is normally off and not conducting current. However, if the compare out line is driven high, indicating a no match, the N channel transistor in the wired OR circuit is turned on thereby coupling the match line to ground. Thus, a no match condition in any one of the bit compare circuits will result in the match line being driven to ground. The performance of the present invention is thereby not affected by the number of bits compared, since the comparison is done simultaneously on a bit-by-bit basis by each of the bit compare blocks coupled to the match line.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 illustrates the dynamic compare circuitry of the present invention.

FIGS. 2(a) and 2(b) illustrate the concept of charge shared preconditioning of the match line utilized by the present invention.

FIG. 3 is a timing diagram of the compare and match circuitry operations of the present invention.

FIG. 4 illustrates the compare block circuitry of the present invention for comparing two binary quantities, including the common mode dip filter.

DETAILED DESCRIPTION OF THE INVENTION

The present invention discloses apparatus and methods for electrically filtering the output of a compare circuit used to compare the contents of two digital words and determine whether or not they identically match. The present invention has broad application in computer memory systems, and in particular, systems which require the filtering of voltage dips generated by sense amplifiers used to sense computer memory cell locations. In the following description, numerous specific details are set forth such as electronic components, data paths, devices, etc., in order to provide a thorough understanding of the present invention. However, it will be apparent to one skilled in the art that the present invention may be practiced without these specific details. In other instances, well known circuits and structures are not described in detail in order not to obscure the present invention unnecessarily.

Although the present invention has broad application in data processing systems requiring the comparison of two binary words, certain aspects of the present invention will be described using terms which represents signals and structures found in the presently preferred embodiment in which the invention is used. For example, in its current form, the present invention compares a data word which is provided to the compare circuit of the present invention with a data word which is sensed from a memory cell. As such, the sensing of the memory cell is accomplished utilizing sense amplifiers. One natural characteristic of a sense amplifier is that prior to the sensed information settling on a line there may be a dip in the voltage level. As will be described, the present invention provides an apparatus and method for negating this natural dip associated with a sense amplifier's output. Although the present invention utilizes sense amplifiers for sensing the content of a memory device, it will be appreciated that the filter of the present invention is not limited for use with sense amplifiers, and may be used in other applications where transient voltage filtering is required. However, for purposes of completeness and clarity, the present invention will be described in the context of a system which utilizes sense amplifiers to obtain one of the binary words to be compared.

Referring now to FIG. 1, the comparison circuit of present invention includes a match line 20. Bit compare blocks 0 through N are coupled to the match line 20 as shown in the Figure. As will be described more fully below, each of the bit compare blocks compares the corresponding bits between a word A and a word B. In this Specification, each of the bit compare blocks compares a bit identified as "TA" for word A, with a bit identified as "SA" for a word B. In the present implementation of the invention, the compare circuit disclosed herein compares a cache memory tag (TA) bit with a sensed cache memory location bit (SA). Each of the bit compare blocks (0 through N) are coupled directly to the match line 20 in a wired OR connection. The bit compare block circuitry of the present invention is dynamic, rather than static, and as such, the speed of comparison of the bits is independent of word length and hereby provides significant system performance improvement over prior art systems.

A latch 15 is coupled to the match line 20 to latch the final result of the compare operations of the bit compare blocks. The latch 15 includes serially coupled inverters 17 and 19. An N channel transistor 21 is coupled to the output of inverter 19 and ground. The gate of transistor 21 is coupled to SAE. In the presently preferred embodiment, the match line 20 is precharged by a charged shared precharge circuit 20. The charge share precharge circuit 20 includes a CMOS passgate 22 coupled to match line 20. The CMOS passgate 22 includes both N channel and P channel devices, and is constructed utilizing CMOS technology. The CMOS passgate 22 includes N channel gate 28 and P channel gate 30. As is known, the application of voltage (V_(cc)) to gate 28 turns N channel gate "on." As illustrated, an inverter 26 is coupled between gates 28 and 30 of the CMOS passgate 22. It will thus be appreciated that the application of V_(cc) to a node 23 results in CMOS passgate 22 being turned on. In addition, an inverter 32 is also coupled between a node 36 and a node 38, as illustrated in the Figures. In the event the CMOS passgate 22 is on, current passes through the passgate between the match line 20 and a match line 50, and node 36 and node 38 are thereby electrically shorted.

The coupling of inverter 32 between nodes 36 and 38 results in the shorting of V_(cc) to ground. In the presently preferred embodiment, the device size of inverter 32 is relatively small, thereby minimizing the current passing over line 40 coupling node 36 to node 38 through the inverter 32. As will be appreciated by one skilled on the art, the shorting of V_(cc) to ground results in a voltage over match line 20 of V_(cc) /2, which corresponds to the trip point of the inverter 32. Thus, in accordance with the teachings of the present invention, the match line 20 is thereby precharged to V_(cc) /2. The inverter 32 acts as a driver for a match signal, thereby permitting the match line 50 to be more heavily loaded than the match line 20.

The present invention further includes a match feedback circuit 45 which is coupled to the charge share precharge circuit 20 as illustrated in FIG. 1. The match feedback circuit 45 further enhances the performance of the present invention by speeding up the process of charging up the match line 20 during a match hit. As shown, the match feedback circuit 45 includes a P channel transistor 47 coupled to V_(cc). The transistor 47 is coupled in series to a second P channel transistor 49, which is in turn coupled to the match line 20. The gate 50 of transistor 47 is coupled to an inverter 52 for receipt of a signal referred to in this Specification as SAE over a line 54. Line 54 is also coupled to the gate 56 of a P channel transistor 58 in the charge share precharge circuit 20. Similarly, the gate 60 of transistor 49 is coupled to the match line 50 at node 38. As shown, a P channel transistor 65 is coupled to V_(cc) in the charge share precharge circuit 20, the gate of transistor 65 being coupled to receive a signal referred to as BEQ . The operation of the charge share precharge circuit 20 and the match feedback circuit 45 will be described more fully below.

In operation, each of the bit compare blocks (0 through N) compare one bit of word A with a corresponding bit of a second word B. As previously noted, each of the bit compare blocks (0 through N) are coupled to the match line 20 in a wired OR configuration. The match line 20 is precharged to a V_(cc) /2 level. At the beginning of a compare cycle, the BEQ signal is driven low, thereby turning the P channel transistor 65 on to permit current to flow from V_(cc). Similarly, at the beginning of a compare cycle, the SAE signal is maintained low, and is coupled to line 54 thereby turning on P channel transistor 58 to permit V_(cc) to pass through that device. As will be appreciated from the illustration of FIG. 1, if transistors 65 and 58 are on, the gate 28 of the CMOS pass gate 22 is also opened as is gate 30. During this period of pre-charge the low SAE signal is inverted by the inverter 52 to turn gate 50 and transistor 47 "off," thereby not permitting current (V_(cc)) to pass there through in the feedback circuit 45. Thus, the match line 20 and the match line 50 are charge shared and precharged to a voltage level of V_(cc) /2. As illustrated in FIG. 3, a line 29 is coupled to node 23, line 29 is further coupled to an N channel transistor 31 which is coupled to ground. The gate of transistor 31 is coupled to a clock (O₂). During the .period of charge shared pre-charge time, clock O₂ is low thereby turning off transistor 31. In the present embodiment, clock O₂ goes high after the match output is valid (see FIG. 5). A high clock O₂ results in transistor 31 being turned on, thereby a coupling match line 20 and match line 50.

The present invention utilizes the concept of charge sharing and precharging of the match line 20 to increase system performance. Referring briefly to FIG. 2, the present invention's concept of charge shared preconditioning of the match line 20 is shown. FIG. 2(b) illustrates the case where a match line is precharged to a voltage level of V_(cc). In the event of a match (or depending upon the logic configuration a "no match"), the result of the compare operation must pull the precharged match line voltage level to ground. The time required to precharge the match line and then to discharge the line to ground degrades system performance. In comparison, the present invention is charge share preconditioning of the match line is illustrated in FIG. 2(a). By precharging match line 20 to V_(cc) /2, the time required to either pull the match line to V_(cc), or to discharge the match line 20 to ground (depending on the logic convention selected), is less than the case illustrated with reference to FIG. 2(b). In other words, the performance of the compare circuit of the present invention is increased because, as illustrated in FIGS. 2(a) and 2(b), T₁ is less than T₂, where T₁ is equal to the time required to either pull the match line 20 up to the V_(cc), or alternatively, to discharge the match line from V_(cc) /2 to ground using the present invention's charge shared precharge conditioning. In the illustration, T₂ is equal to the time required to discharge the match line from V_(cc) to ground.

Referring once again to FIG. 1, in conjunction with the timing diagram of FIG. 3, the operation of the present invention will be described in further detail. In FIG. 3, a clock signal (Clk) is provided to the system of the present invention. The clock signal may be generated from an internal or external clock source. At the beginning of a compare cycle, the rising edge of the clock signal (80) results in the generation of a BEQ signal driven "high", and a corresponding BEQ signal driven low (identified by the numeral 82). The BEQ signal is followed after a predefined time T_(c) by the generation of an SAE signal driven high (numeral 84). With reference to FIG. 1, as previously described transistors 47 and 49 are P channel devices, such that the transistors are "on" when there is no voltage at the gates 50 and 60, respectively. In order for transistor 47 to pass current, the voltage at gate 50 must be low (V_(ss)). Similarly, in order for transistor 49 to pass current, the voltage at gate 60 must be low (V_(ss)) as well. In comparison, CMOS passgate 22 includes N channel gate 28 which is on when V_(cc) is provided to the gate 28. In order for gate 28 to be on, transistor 65 and transistor 58 must also be on since they are coupled to V_(cc).

It will be appreciated that since transistors 65 and 58 are P channel devices, BEQ and line 54 which is coupled to SAE must be low in order for V_(cc) to be coupled to gate 28, and thereby precharge match line 20. As best shown in FIG. 3, the time period between signal BEQ driven low and signal SAE driven high corresponds to the match line precharge time (T_(c)) of the present invention. The match line precharge time (T_(c)) is the time period during which match line 20 is precharged to V_(cc) /2. As will be appreciated from the figures, upon signal SAE being driven high, gate 56 of transistor 58 is closed thereby preventing current from passing through transistor 58 and not providing a V_(cc) voltage to gate 28. Consequently, upon signal SAE being driven high, the transistor 58 is shut off, as is gate 28 thereby preventing further precharging of the match line 20. The timing for driving the SAE signal high thus terminating the T_(c) time is a matter of design choice based on design considerations. For purposes of this description, the mechanism employed by the present invention for the generation of signals BEQ, BEQ and SAE are not described in further detail. A consideration in the implementation of the present invention is that the match line precharge time (T_(c)) be sufficient to accomplish the precharging of match line 20 to V_(cc) /2.

As illustrated in FIG. 3, as the SAE signal is driven high (84), the match line precharge is terminated and the bits from a first word (SA) are coupled to the bit compare blocks 0 through N. In the presently preferred embodiment of the invention, the bits comprising word B to be compared (bits SA₀ through SA_(N)) originate from an on chip memory block. Similarly, bits comprising word A to be compared with the bits for word B are coupled in the present embodiment from an external bus to the bit compare blocks 0 through N. Using the convention in this specification, the bits of word A (bits TA₀ through TA_(n)) are compared with the corresponding bits of word B (bits SA₀ through SA_(N)). As shown in the timing diagram of FIG. 3, the bits of word A (TA₀ through TA_(N)) are coupled to each of the bit compare blocks prior to the completion of the precharge of the match line 20. The bits of word B are coupled to the bit compare blocks upon the termination of the match line precharge time as a result of the SAE signal going high (84). The timing for providing the bits of word B to the bit compare blocks is designed to permit sufficient time for the match line 20 to be precharged. In addition, as will be described, the present invention's bit compare blocks include circuitry which compensates for natural voltage dips in sense lines due to the electrical characteristics of sense amplifiers. In the current implementation, the signal SAE corresponds to a sense amplifier enable signal which is coupled to a cache memory for reading a memory location to be compared to an externally provided tag word. However, it will be appreciated that the operation and performance advantages taught by the present invention have application far beyond the current implementation.

Continuing to refer to FIG. 3, the bit compare blocks 0 through N compare the bits comprising word A (bits TA₀ through TA_(N)) with the bits comprising word B (bits SA₀ through SA_(N)) upon receipt of the bits comprising word B. As illustrated in the timing diagram, the coupling of bits SA₀ through SA_(N) to the bit compare circuits (see point 90) results in the match output of the present invention on match line 20. The state of the match line 20 is latched by the latch 15. It will be noted that during the compare/latch period when the match output is sensed the charge share precharge circuit 20 electrically disconnects match line 20 from match line 50. The rising edge of the BEQ signal (identified as numeral 92) results in the turning off of transistor 65 thereby not permitting current to pass through the device. Similarly, the rising edge of BEQ (92) is followed by the SAE signal being driven low (indicated by the numeral 94). A low SAE signal results in the opening of the gate 56 of transistor 58, turning transistor 58 on, and the closing of gate 50 thereby turning transistor 47 off. Since BEQ is high, transistor 65 is turned off and V_(cc) is not coupled through transistor 65 to the transistor 58. Thus, a high signal at gate 50 of the transistor 47 results in the transistor 47 being "off" and not permitting V_(cc) to pass therethrough. Accordingly, during the period in which the match output is provided by the bit compare blocks 0 through N and latched on match line 20, match line 20 is electrically disconnected from match line 50.

Continuing to refer to FIG. 1 in conjunction with FIG. 3, during the compare/latch period for the match line 20, the latch 15 maintains the state (match or no match) of the match line 20. This state is inverted by the inverter 32 which also acts as a match driver. This driver boosts the match line 20 in the event match line 20 detects a hit by providing feedback into the gate of transistor 49.

Referring to FIG. 4, the bit compare block circuitry of the present invention will be described with reference to an exemplary bit compare block (N). As shown, the bit compare block N includes a compare circuit 100, a common mode dip filter circuit 102, and a wired OR circuit 104. The compare circuit 100 effectively comprises an exclusive NOR gate which is provided with bit A_(N) and bit B_(N) for comparison. Consistent with the syntax set forth in this description, and previously discussed with reference to FIG. 1, the bits A_(N) and B_(N) are denoted as TA_(N1), TA_(N1), SA_(N) and SA_(N). The value of SA_(N) and SA_(N) is provided in the present embodiment, from an on chip memory block (not shown). The values of TA_(N) and TA_(n) are provided from an external bus (not shown).

The output of the compare circuit 100 is coupled to the input of the common mode dip filter 102 by a line 120. As will be described, the common mode dip filter 102 avoids the spurious generation of ambiguous compare results, by filtering out undesirable voltage dips generated through the use of sense amplifiers to sense the contents of memory. As previously noted, the presently preferred embodiment utilizes sense amplifiers to sense a cache memory and to provide the output of the memory as bit SA_(N) (and its inverted value SA_(N)) to the compare circuit 100, for comparison with a static bit value coupled from an external bus (TA_(N) and TA_(N)).

Continuing to refer to FIG. 4, present invention is coupled to the wired OR circuit 104 by a compare out line 110. The output of the common mode dip filter 102 is normally maintained in a low state, thereby indicating a match has occurred. The wired OR circuit 104 includes an N channel transistor 112 having a gate 114 which is turned on by line 110 being driven high. If the state of line 110 remains low, the transistor 112 remains off. In the event that a single bit in any of the bit compare blocks (0 through N) does not match, the line 110 in the non-matching bit compare circuit is driven high, thereby opening gate 114 and turning on N channel transistor 112. If transistor 112 is on, the precharge voltage V_(cc) /2 on the match line 20 is pulled to ground.

For the sake of example, assume TA_(N) is high (and consequently TA_(N) is low). A CMOS passgate 116 in the compare circuit 100 is turned on and the corresponding CMOS passgate 118 is turned off. In the compare circuit 100 illustrated in FIG. 4, if either the CMOS passgate 116 or the CMOS passgate 118 is on, the other is necessarily turned off. If SA_(N) is high and TA_(N) is high, then CMOS passgate 116 is on thereby resulting in line 120 being driven high. Conversely, if SA_(N) is low and TA_(N) is high, line 120 will remain low since the CMOS passgate 118 is turned off.

The present invention's use of sense amplifiers to sense memory locations to provide the SA_(N) and SA_(N) signals are high at the beginning of a cycle and result in a condition where both SA_(N) and SA_(N) dip simultaneously low. The condition where SA_(N) and SA_(N) dip simultaneously low is due to the analog nature of the signals, and the electrical characteristics of sense amplifiers. It will be appreciated that if SA_(N) and SA_(N) dip low, line 120 will go low regardless of the state of TA_(N) or TA_(N). The condition where SA_(N) and SA_(N) dip simultaneously low is a transitory dip where the voltage along line 120 dips low which could result in a false high signal over line 110 indicating a no match condition on the match line 20. To compensate for the possibility of the sense amplifier's electrical transitory dips causing a false result, the common mode dip filter 102 is coupled with the output of the compare circuit 100 over output line 120.

As illustrated, the common mode dip filter includes a P channel transistor 122 coupled to V_(cc), and as shown, an additional P channel transistor 128 is coupled between transistors 122 and 124 to ground. The gate 130 of P channel transistor 128 is coupled to the compare output line 110. In addition, an N channel transistor 126 is coupled to line 120 as illustrated. In operation, if line 120 is remains high, P channel transistors 122 and 124 remain off and N channel transistor 126 remains on. If transistor 126 is on, the compare out line 110 is coupled to ground. Alternatively, if line 120 is driven low, P channel transistors 122 and 124 are turned on, thereby coupling V_(cc) to the compare out line 110 and driving the compare out line 110 high. As previously noted, driving the compare out line 110 high turns on transistor 112 in the wired OR circuit 104 and pulls the match line 20 to ground.

It will be appreciated that a temporary dip in the voltage level of 120 resulting from, for example, a sense amplifier voltage dip, does not result in a change of state in the compare outline 110. The output of line 120 is filtered through the placement of P channel transistor 128 between P channel transistors 122, 124 and ground. In the event that line 120 dips low, a node 140 is pulled high by V_(cc) and is simultaneously pulled low through transistor 128 to ground. In the absence of transistor 128, a low state of line 120 would result in N channel transistor 126 turning off, and P channel transistors 122 and 124 turning on, thereby pulling the compare outline 110 to high and generating a false "no match". However, since the compare out line 110 is coupled to gate 130 of the P channel transistor 128, a high state at gate 130 results in transistor 128 turning off. Thus, there is a coupling between V_(cc) and ground resulting in a loss of power, and a filtering of short time duration voltage dips over line 120. In order to change the state of compare outline 110 it is necessary for line 120 to be driven low in a solid manner to force the compare outline 110 to be driven high. Relatively small variations in the voltage level over line 120 will not result in the compare out line 110 being driven high, thereby avoiding in spurious false signals to the wired OR circuit 104.

It will be further noted that since the match line 20 is precharged to V_(cc) /2, in the event that all bit compare blocks 0 through N indicate a "match", the match line 20 will change to V_(cc) through match feedback circuit 45. SAE going high raises the match line 20 level slightly above the trip point of inverter 32. In the event of a "match", inverter 32 drives node 38 low which turns transistor 49 on, thereby charging match line 20 to V_(cc). However, if any one of the compare out lines (line 110 in FIG. 4) in any of the bit compare blocks are driven high, thereby indicating that a no match condition occurs, the transistor corresponding to transistor 112 is turned on, thereby driving the state of the match line 20 to ground. Accordingly, the present invention's dynamic compare circuit as described herein is independent of the word size being compared. Since a comparison of the corresponding bits between word A and word B is accomplished simultaneously and independent of one another, the bit length of words A and B are not a factor in determining the speed of the comparison operation. If any one of the bits (0 through N) do not match between the compared words, the match line 20 is pulled low. The state of the match line 20 is then latched by latch 15, and the inverted state of the match line (match) is provided as an output on match line 50.

As disclosed herein, the present invention provides an improved high performance comparison circuit. The comparison circuit of the present invention includes a charge share precharge circuit and a match feedback circuit for providing a very high speed precharge to a match line. Moreover, the present invention provides one bit compare block for each bit to be compared. Each bit compare block includes a compare circuit coupled to a common mode dip filter. The common mode dip filter filters out unwanted transient voltage variations which may be generated through the use of, for example, sense amplifiers to sense the condition of memory elements. The common mode dip filter provides a compare output signal to a wired OR circuit, which is in turn coupled to the match line 20. Although the present invention has been described with reference to FIGS. 1 through 4, it will be appreciated that the present invention may be utilized in a variety of systems where the filmring of transient voltage levels is required. The description herein with reference to the figures will be understood to describe the present invention in sufficient detail to enable one skilled in the art to utilize the present invention in a variety of applications and system environments. 

We claim:
 1. A circuit for filtering transient voltage dips., comprising:an input line; a first transistor coupled to a voltage source (V_(cc)) and coupled in series to a second transistor coupled to ground, said first transistor including a gate coupled to said input line; a third transistor coupled to ground and to an output line, said third transistor including a gate coupled to said input line, said third transistor further being coupled to said first transistor; said second transistor including a gate, said gate of said second transistor coupled to said output line, and wherein; said first and second transistors are comprised of a first transistor type different from said third transistor, such that if a voltage applied to said gates of said first and second transistors turns said first and second transistors off, said third transistor is turned on.
 2. The circuit as defined by claim 1 further including a fourth transistor of the same type as said first and second transistors, said fourth transistor coupled between said first and third transistors, said fourth transistor including a gate coupled to said input line.
 3. The circuit as defined by claim 2 wherein said first, second and fourth transistors are of the P channel type.
 4. The circuit as defined by claim 3 wherein said third transistor is of the N channel type.
 5. The circuit as defined by claim 4 wherein said input line is normally maintained at a voltage level of approximately V_(cc), such that said first and fourth transistors are off and said third transistor is on.
 6. The circuit as defined by claim 5 wherein if said input line is approximately V_(cc) said output line is pulled to ground.
 7. The circuit as defined by claim 6 wherein in the event said voltage of said input line drops to a lower voltage level than Vcc, said first, second and fourth transistors are on, and said third transistor is off, thereby coupling Vcc to ground.
 8. The circuit as defined by claim 7 wherein if said voltage level of said input line drops to said lower voltage level for a predetermined time, said output line is pulled toward Vcc.
 9. A circuit for filtering out transient voltage dips in an input line, said input line normally driven to a voltage of approximately Vcc, said circuit comprising:a first P channel transistor coupled to Vcc, said first transistor including a gate coupled to said input line; a second P channel transistor coupled in series to said first transistor, said second transistor including a gate coupled to said input line; an N channel transistor coupled in series to said second P channel transistor and to ground, said N channel transistor further coupled to an output line, said output line normally pulled to a ground; a third P channel transistor coupled between said first and second P channel transistors, said third P channel transistor further coupled in series to ground and having a gate coupled to said output line.
 10. The circuit as defined by claim 9 wherein if said input line is approximately Vcc said output line is pulled to ground.
 11. The circuit as defined by claim 10 wherein in the event said voltage of said input line drops to a lower voltage level than Vcc, said first, second and third transistors are on, and said N channel transistor is off, thereby coupling Vcc to ground.
 12. The circuit as defined by claim 11 wherein if said voltage level of said input line drops to said lower voltage level for a predetermined time, said output line is pulled toward Vcc.
 13. The circuit as defined by claim 12 wherein said input line is coupled to the output of a compare circuit.
 14. The circuit as defined by claim 13 wherein said output line is coupled to the input of a wired OR circuit.
 15. The circuit as defined by claim 14 wherein said wired OR circuit includes a second N channel transistor coupled in series between ground and a match line, said second N channel transistor having a gate coupled to said output line.
 16. The circuit as defined by claim 15 wherein said filter circuit, said compare circuit and said wired OR circuit comprise a bit compare circuit, said bit compare circuit comparing a first bit provided from a first data word with a corresponding first bit from a second data word.
 17. The circuit as defined by claim 16 further including a plurality of said bit compare circuits, each of said bit compare circuits coupled to said match line.
 18. The circuit as defined by claim 17 wherein said bit compare circuits operate in parallel with one another and provide an output from each of said wired OR circuits, such that if any one of said corresponding bits of said first and second data words do not match said match line is pulled to ground.
 19. The circuit as defined by claim 18 further including sensing means coupled to said match line for sensing, the state of said match line to determine if said first and second data words identically match. 